System and Method to Provide Safety Partition for Automotive System-On-A-Chip

1. An automotive control system, comprising: a safety processor; and a system-on-a-chip (SoC), including: a primary processor; a safety monitor configured to detect a fault condition of the primary processor and to provide an indication of the fault condition to the safety processor; a first general purpose input/output (GPIO) bank coupled to the primary processor for communication to control a non-critical function of an automobile; a second GPIO bank coupled to the primary processor for communication to control a first critical function of the automobile; and a debug interface coupled to the second GPIO bank to form a first scan chain with input and output registers of the second GPIO bank, the debug interface coupled to the safety processor to receive first control information for the first scan chain to control the first critical function of the automobile based on the indication of the fault condition.

2. The automotive control system of claim 1 , further comprising: a primary voltage regulator coupled to provide power to the primary processor, the safety monitor, and the first GPIO bank; and a safety voltage regulator coupled to provide power to the safety processor, the debug interface, and the second GPIO bank.

3. The automotive control system of claim 2 , wherein the SoC further includes a watchdog module coupled to the safety voltage regulator, and coupled to receive the indication from the safety monitor.

4. The automotive control system of claim 3 , wherein the watchdog module is configured to determine that the primary voltage regulator is not providing power, and in response to provide the indication to the safety processor.

5. The automotive control system of claim 1 , wherein: the SoC further includes a third GPIO bank coupled to the primary processor to provide input/output operations to a second critical function of the automobile, and the debug interface is further coupled to the third GPIO bank to form a second scan chain with input and output registers of the third GPIO bank, and is further coupled to the safety processor to receive second control information for the second scan chain to provide input/output operations to the second critical function of the automobile when the safety monitor provides the indication.

6. The automotive control system of claim 1 , wherein the SoC further includes the safety processor.

7. The automotive control system of claim 1 , wherein the first scan chain is a Joint Testing and Access Group (JTAG) scan chain.

8. The automotive control system of claim 1 , wherein the debug interface is coupled to the safety processor via a Test Access Port (TAP).

9. A method for providing control of automobile functions, the method comprising: coupling a primary processor of a system-on-a-chip (SoC) of an automotive control system to a first general purpose input/output (GPIO) bank of the SoC, and to a second GPIO bank of the SoC, wherein the first GPIO bank is associated with a non-critical function of an automobile and the second GPIO bank is associated with a first critical function of the automobile; coupling a debug interface of the SoC to the second GPIO bank to form a first scan chain with input and output registers of the second GPIO bank; coupling the debug interface to a safety processor of the automotive control system to receive first control information for the first scan chain to control the first critical function of the automobile; providing, by the safety monitor, an indication of the fault condition to the safety processor; and providing, by the safety processor, the first control information in response to receiving the indication.

10. The method of claim 9 , further comprising: connecting a primary voltage regulator of the automotive control system to provide power to the primary processor, the safety monitor, and the first GPIO bank; and connecting a safety voltage regulator of the automotive control system to provide power to the safety processor, the debug interface, and the second GPIO bank.

11. The method of claim 10 , further comprising: connecting a watchdog module of the SoC to the safety voltage regulator; and coupling the watchdog module to receive the indication from the safety monitor.

12. The method of claim 11 , further comprising: determining, by the watchdog module, that the primary voltage regulator is not providing power; and providing, by the watchdog module, the indication to the safety processor in response to determining that the primary voltage regulator is not providing power.

13. The method of claim 9 , further comprising: coupling the primary processor to a third GPIO bank, wherein the third GPIO bank is associated with a second critical function of the automobile; coupling the debug interface to the third GPIO bank to form a second scan chain with input and output registers of the third GPIO bank; coupling the debug interface to the safety processor of the automotive control system to further receive second control information for the second scan chain to control the second critical function of the automobile; and providing, by the safety processor of the automotive control system, the second control information in response further to receiving the indication.

14. The method of claim 9 , wherein the SoC further includes the safety processor.

15. The method of claim 9 , wherein the first scan chain is a Joint Testing and Access Group (JTAG) scan chain.

16. The method of claim 9 , wherein the debug interface is coupled to the safety processor via a Test Access Port (TAP).

17. An automotive control system, comprising: a system-on-a-chip (SoC), including: a primary processor; a safety processor; a safety monitor configured to detect a fault condition of the primary processor and to provide an indication of the fault condition to the safety processor; a first general purpose input/output (GPIO) bank for communication to control a non-critical function of an automobile, the first GPIO bank coupled to the primary processor; a second GPIO bank for communication to control a critical function of the automobile; and a multiplexor including a first input coupled to the primary processor, a second input coupled to the safety processor, a selector input coupled to the safety processor, and an output coupled to the second GPIO bank, wherein, based on the indication, the safety processor is configured to assert a selector signal to the selector input and to provide input/output operations to the critical function of the automobile.

18. The automotive control system of claim 17 , further comprising: a primary voltage regulator coupled to provide power to the primary processor, the safety monitor, and the first GPIO bank; and a safety voltage regulator coupled to provide power to the safety processor, the multiplexor, and the second GPIO bank.

19. The automotive control system of claim 18 , wherein the SoC further includes a watchdog module coupled to the safety voltage regulator, and configured to receive the indication from the safety monitor.

20. The automotive control system of claim 19 , wherein the watchdog module is configured to determine that the primary voltage regulator is not providing power, and in response, provide the indication to the safety processor.